121172017-09-18An MMOD Risk Mitigation Technology for Spacecraft TPSCompletedOct 2011Sep 2013<p>The proposed project uses multiple and different types of sensors to detect high temperature plasma ingestion during atmospheric entry through a breach up to one-inch diameter in the Thermal Protection System (TPS) caused by an Micro-Meteoroid and Orbital Debris (MMOD) impact. Once high temperature plasma ingestion is detected during atmospheric entry, this technology can be automatically activated and uses consumables usually available on human-rated spacecrafts such as nitrogen (or helium) and water to (1) equalize the internal pressure to that of the external pressure across the breach to prevent high temperature plasma from penetrating the spacecraft and (2) maintain spacecraft structural integrity by keeping it within the temperature limits via an evaporative cooling effect.<p/><p>This proposed technology uses nitrogen or helium gas and water to prevent structural damage that could lead to loss of vehicle and loss of crew caused by high temperature plasma ingestion through an MMOD impacted damage in the TPS. This results in "enhanced safety and probability of mission success for Entry, Descent, and Landing (EDL) phases of atmospheric flight." This technology uses heat flux, temperature, and pressure sensors from the Fault Detection Isolation and Recovery (FDIR) system to detect high temperature plasma ingestion. Thus, this system integrates gaseous nitrogen and water from the Environment Control and Life Support System (ECLSS) and the sensors from FDIR systems to automatically activate when necessary to mitigate the potential catastrophic hazard.</p><p><p>This proposed technology is a crosscutting technology that enables on-board vehicle systems management to detect a breach in the TPS during the critical entry phase and to autonomously activate the system to prevent plasma ingestion and to prevent structural failure that leads to loss of crew, loss of vehicle, and loss of mission.&nbsp; This proposed technology works autonomously, thus reducing earth-based mission ops &ldquo;back room engineering&rdquo; requirements for distant mission support delay.</p></p>22332394Robotics and Autonomous Systems32784.5System-Level Autonomy32479Entry, Descent, and Landing Systems324013Ground and Launch Systems324114Thermal Management SystemsCenter Innovation Fund: JSC CIFSpace Technology Mission DirectorateJohnson Space CenterJSCNASA CenterHoustonTXTexasTherese GriebelVuong PhamVuong Pham172 Patent Link 1Linkhttp://Waiting for the results of the demonstration test scheduled in September 2013 at JSC's Arc Jet Facility101812117-1376504576177.jpgImageProject Image An MMOD Risk Mitigation Technology for Spacecraft TPS2215https://techport.nasa.gov/file/221564175173NTR 1Linkhttp://NTR MSC #: MSC-25369-1